Circuit arrangement for a display device which can be operated in a partial mode

ABSTRACT

The invention relates to a circuit arrangement for controlling a display device ( 2 ) which can be operated in a partial mode, comprising a row drive circuit ( 4 ) for driving n rows of the display device ( 2 ) and a column drive circuit ( 3 ) for driving m columns of the display device, wherein the row drive circuit ( 4 ) controls the n rows of the display device sequentially from 1 to n, and the column drive circuit ( 3 ) supplies column voltages to the m columns, which voltages correspond to the picture data to be displayed of pixels of the controlled row. The invention further relates to a display device with such a circuit arrangement, a row drive circuit for a display device, an electronic appliance with a display device, and a method of realizing a partial mode. To keep the construction for realizing a partial mode simple, it is suggested that a logic function is connected in front of at least one output of the row drive circuit ( 4 ), to which function a first control signal (R E ) is supplied which achieves a deactivation of all row outputs (Z 1  to Z n ) of the row drive circuit ( 4 ) in the case of a row (Z 3 , Z 4 ) that is not to be displayed, and an activation of all row outputs (Z 1  to Z n ) in the case of a row (Z 1 , Z 2 , Z 5 ) that is to be displayed. This renders it possible to realize a partial mode through the supply of only a single control signal (R E ) to the row drive circuit without the second control signal (R P ) necessary for controlling the rows having to be deactivated for the rows not to be displayed in the partial mode in the process of controlling the consecutive rows in the row drive circuit.

The invention relates to a circuit arrangement for controlling a display device which can be operated in a partial mode, comprising a row drive circuit for driving n rows of the display device and a column drive circuit for driving m columns of the display device, wherein the row drive circuit controls the n rows of the display device sequentially from 1 to n, and the column drive circuit supplies column voltages to the m columns, which voltages correspond to the picture data to be displayed of pixels of the controlled row. The invention further relates to a display device with such a circuit arrangement, a row drive circuit for a display device, an electronic apparatus with a display device, and a method of realizing a partial mode on a display device.

Display technology claims an ever more important role in information and communication technology. As an interface between man and the digital world, a monitor device or a display is of central importance for the acceptance of modem information systems. It is in particular portable apparatuses such as, for example, notebooks, telephones, digital cameras, and personal digital assistants that cannot be realized without the use of displays. There are two kinds of displays in principle. These are on the one hand passive matrix displays, and on the other hand active matrix displays. The invention relates in particular to passive matrix displays which are used inter alia in laptop computers and mobile telephones. Large displays can be realized in passive matrix display technology, most of these being based on the (S)TN (Super Twisted Nematic) effect.

Energy consumption is a particularly important criterion in portable electronic devices, because the service life of the battery of the device, and thus the period of use of the device, is dependent thereon. A frequently used method of saving energy is offered by the partial mode. Partial regions of the display are activated only in this mode. The inactive regions of the display and also the components necessary for controlling these regions are switched off, so that they require no energy.

A passive matrix display is basically constructed in the form of a matrix. The display is controlled via column supply lines and row supply lines which are arranged perpendicularly to one another. The supply lines to the columns and rows are present on different glass substrates, between which a liquid crystal is present. Addressing of the display is passive, i.e. there is no active switch (for example a thin-film transistor) for each individual pixel. Instead, the information is sequentially written into the display row by row by means of suitable combinations of voltages applied to the rows and columns. The pixel can be set for at least two different switching states by means of different voltages applied to the column and row contacts. A single pixel is formed by the intersection of one column supply line and one row supply line. The material used for the rows and columns is, for example, transparent indium-tin oxide (ITO).

A partial mode is realized in known circuit arrangements in that the signal controlling the rows of the row drive circuit is conducted past rows that are not to be displayed by means of complicated multiplex circuits, such that this signal does not arrive at the row output point for the row that is not to be displayed. This requires a high expenditure in achieving a communication between the control logic and the row drive circuit.

It is an object of the invention to provide an arrangement for controlling a display device in which the expenditure for realizing a partial mode and thus also the energy consumption and cost of the display device are reduced.

This object is achieved with a circuit arrangement for controlling a display device which can be operated in a partial mode, comprising a row drive circuit for driving n rows of the display device and a column drive circuit for driving m columns of the display device, wherein the row drive circuit controls the n rows of the display device sequentially from 1 to n, and the column drive circuit supplies column voltages to the m columns, which voltages correspond to the picture data to be displayed of pixels of the controlled row and wherein in addition a logic function is included in the row drive circuit in front of at least one row output, to which logic function a first control signal can be supplied, said first control signal achieving a deactivation/activation of the row output in dependence on the partial mode.

It is necessary in realizing a partial mode to implement a control logic both in the column drive circuit and in the row drive circuit, by means of which logic individual rows can be deactivated. It is furthermore necessary in the supply of the column voltages to feed only those column voltages which are designed for pixels in rows which are to be shown or activated. The column and row drive circuits are interrelated via control lines, through which the control commands or signals are exchanged.

It is suggested according to the invention that row outputs of the row drive circuit for rows which should not be shown in the partial mode or which are inactive are switched off or deactivated by means of a first control signal (row_enable). This first control signal (row_enable) is supplied to the row drive circuit of a control logic which is arranged in the row drive circuit. A row counter is present in the control logic. This row counter runs through the number of rows of the display from 1 to n. It is thus known to the control logic at each and every moment which row is being controlled. The control logic controls the supply of voltages to the column supply lines corresponding to the picture data of the instantaneous row to which column voltages are applied. In the case of a row which is not to be displayed, no new voltage values are applied to the column lines. The voltages applied to the column lines remain applied thereto until a row is controlled which is to be displayed. That means that the column voltages applied to the previous row to be displayed remain applied for a row not to be displayed. Since the row not to be displayed is not controlled, i.e. receives no voltage from the row supply line, no pixels are shown in this row, because a display of pixels in a row takes place only if a voltage is present on both of the intersecting conductor tracks, which leads to a state change or a rotation of the crystals in this pixel, whereby this pixel is made visible.

The row drive circuit is operated with a clock signal (row clock). The clock signal indicates the speed with which a jump is made from one row to the next. This clock signal accordingly influences the duration necessary for traversing the n rows of a display. The necessary control logic in the row drive circuit is thus reduced to those logic functions which can be realized by means of simple AND gates. Only one signal need be transmitted from the control logic in the row drive circuit for deactivating or activating row outputs for a partial mode.

In an advantageous embodiment of the invention, a shift register is provided in the row drive circuit such that the number n of the outputs and stages of the shift register corresponds to the number of rows of the display. A logic function is associated with at least one output of the shift register. Preferably, a logic function is associated with each output of the shift register. This logic function is connected between the relevant output of the shift register and the row output each time. The first control signal (row_enable) is supplied to the at least one logic function. Preferably, it is supplied to all logic functions. This renders it possible to achieve the deactivation/activation of the row outputs for realizing a partial mode by means of no more than the first control signal.

A second control signal (row_pulse) is supplied to the input of the shift register and is shifted step by step through the shift register. The second control signal (row_pulse) is shifted one row or step further in the shift register with each pulse of the clock signal.

When this second control signal arrives at a row which should remain inactive in the partial mode, according to the invention, all row drive outputs are switched to a deselect mode by the logic function. The first control signal (row_enable) is preferably supplied by the column drive circuit during this. Accordingly, the second control signal is indeed applied to the output of the shift register for the relevant row at that moment, but it cannot switch on the corresponding row drive output because all row drive outputs are switched off by means of the first control signal (row_enable) applied to the logic function. The second control signal accordingly continues to the next row with the next clock signal. If this row is to be displayed in the partial mode, the first control signal releases all logic functions again, and thus also the row outputs, so that the second control signal (row_pulse) can switch on or activate the corresponding next row output, and the relevant picture data can be displayed in this row thanks to the column voltages applied to the column inputs at the same time.

In an advantageous embodiment of the invention, the rhythm of the clock signal is increased for rows not to be displayed during the traversal of the second control signal through the stages of the shift register. The total traversal time for all rows in the partial mode is shortened thereby, which results in a faster refresh of the display, and image changes or moving images can be better displayed in the partial mode. In addition, the increase in the clock frequency for inactive rows renders it possible to reduce the voltages applied to the rows and columns to be displayed, which leads to a considerable energy saving because the effective number of rows of the display in the partial mode is only the number of active or displayable modes. The more rows are controlled, the higher the voltages have to be which are to be applied to the rows and columns for achieving a good display quality. A reduction in the number of rows to be controlled is also denoted a reduction in multiplexibility.

In an alternative embodiment of the invention, the clock frequency is increased for deactivated rows, whereas the clock frequency is reduced for active rows, such that the refresh rate remains constant in the partial mode for a traversal of all rows of the display. This also leads to an energy saving.

In a further advantageous embodiment of the invention, the logic functions are provided only at those row outputs which are designed for the partial mode. In certain embodiments of displays, the layout of the display defines beforehand in which rows picture data are to be displayed in the partial mode.

The supply of the first control signal (row_enable) to all connected logic functions of the row outputs renders it possible to realize a partial mode by means of a single additional signal, without the necessity of constructing the control logic of the row drive circuit in a complicated manner for a partial mode and exchanging a plurality of control commands between the column drive circuit and row drive circuit.

The invention here utilizes the idea that the full power level or display level of a portable electronic device is usually required for a short period only. Simplified displays are usually sufficient in the remaining time. The partial mode used here, in which the display is only partly driven, leads to a simplification of the control logic, so that the components can become less expensive and consume less energy.

The object is also achieved by means of a row drive circuit for controlling n rows of a display device with n outputs, wherein a logic function is connected in front of each row output, by means of which function the row outputs can be deactivated/activated in dependence on a partial mode upon the supply of a first control signal.

The object is also achieved by means of a display device with a circuit arrangement as claimed in claims 1 to 8.

The object is further achieved by means of an electronic apparatus in which a display device for realizing a partial mode as claimed in claim 9 is used.

The object is further achieved by means of a method of realizing a partial mode, whereby a display device is controlled by a circuit arrangement comprising a row drive circuit and a column drive circuit, and wherein logic functions in the row drive circuit receive a first control signal such that the first control signal deactivates/activates row outputs of the row drive circuit in dependence on a partial mode to be displayed of the row drive circuit.

Embodiments of the invention will be explained in more detail below with reference to the drawing, in which:

FIG. 1 is a block diagram of the control of a display device,

FIG. 2 shows a row drive circuit, and

FIG. 3 shows signal gradients.

In FIG. 1, a block diagram shows the control of a display 2. A column drive circuit 3 and a row drive circuit 4 are connected to the display. The picture data to be displayed are stored in a memory (not shown) or are generated by a unit which is not shown.

The control logic 5 controls the voltage supply in the column drive circuit 3 and the supply of the control signals to the row drive circuit 4. The rows of the display are switched on consecutively by the row drive circuit 4, i.e. a suitable column voltage is supplied to the row whose turn it is at any given moment. The column drive circuit 3 supplies voltages to the columns of the display, corresponding to the picture data which are to be displayed in the current row. The pixels of the current row assume a state based on the combination of the column voltages and the row voltage which corresponds to the picture data to be displayed. After a row of the display has been controlled and the picture data have been shown, the row drive circuit controls the next row. The column drive circuit then supplies the corresponding column voltages which correspond to the picture data of this next row. After all rows of a display have been traversed, a new cycle is started.

FIG. 2 is a detailed representation of a row drive circuit 4. The row drive circuit 4 comprises row outputs Z₁ to Z_(n). A shift register 41 is furthermore provided, with stages S_(n), the number of stages S_(n) corresponding to the number of rows of the display 2. The stages S_(n) in this embodiment comprise flipflops F₁ to F_(n). The second control signal R_(P) (row_pulse) is supplied to the shift register in its first stage F₁. This second control signal R_(P) is put into the shift register 41 in the form of a pulse each time when the row counter in the control logic starts counting anew at row 1. The shift register is operated with a clock signal T, i.e. the second control signal R_(P) (row_pulse) is shifted one step S in the shift register with each clock pulse. With each new clock pulse, accordingly, the second control signal R_(P) is applied on the one hand to the respective output A₁ of the active stage S₁ of the shift register 41, and on the other hand also to the input of the next stage S₂. Furthermore, the first control signal R_(E) is supplied to the row drive circuit 4. This first control signal R_(E) is supplied to all connected logic functions L₁ to L_(n). The respective second control signal R_(P) applied to the relevant output A₁-A_(n) of the shift register is only passed on to the relevant row output Z₁-Z_(n) if all rows are released or activated by the first control signal R_(E). If the rows are deactivated or blocked by the first control signal R_(E), a second control signal R_(P) applied to the output A₁-A_(n) of the shift register 41 is not switched through to the row outputs. The row drive circuit 4 is fitted with an amplifier V at each row output Z₁-Z_(n) for amplifying the second control signal to the required row voltage.

FIG. 3 shows the signal gradients of the first control signal R_(E), the second control signal R_(P), the clock signal T, and the signals at the row outputs Z₁-Z₅. At the first clock pulse, the second control signal R_(P) is read into the shift register, and at the second clock pulse the first control signal R_(P) is passed on to the row output Z₁, because the first control signal R_(E) has switched all row outputs to the active state. The third clock signal issues the second control signal R_(P) to the row output Z₂. Now the first control signal R_(E) changes to the inactive state, i.e. all row outputs Z₁ to Z_(n) are blocked by means of the logic functions, so that the second control signal R_(P) cannot be switched through to the row outputs Z₃ and Z₄ during the next two clock periods. At the same time, the clock frequency is increased for the period in which the first control signal R_(E) is in the inactive state. It is not until the first control signal R_(E) returns to the active state again that the clock frequency is reduced again, and the second control signal R_(P) is passed on to the row output Z₅. 

1. A circuit arrangement for controlling a display device (2) which can be operated in a partial mode, comprising a row drive circuit (4) for driving n rows of the display device (2) and a column drive circuit (3) for driving m columns of the display device, wherein the row drive circuit (4) controls the n rows of the display device sequentially from 1 to n, and the column drive circuit (3) supplies column voltages to the m columns, which voltages correspond to the picture data to be displayed of pixels of the controlled row, characterized in that a logic function (L₁-L_(n)) is included in the row drive circuit (4) in front of at least one row output (Z₁-Z_(n)), to which logic function a first control signal (R_(E)) can be supplied, said first control signal (R_(E)) achieving a deactivation/activation of the row output (Z₁-Z_(n)) in dependence on the partial mode.
 2. A circuit arrangement as claimed in claim 1, characterized in that the logic function (L₁-L_(n)) is connected in front of each row output (Z₁-Z_(n)).
 3. A circuit arrangement as claimed in claim 1, characterized in that the logic function (L₁-L_(n)) is realized as an AND gate.
 4. A circuit arrangement as claimed in claim 1, characterized in that the row drive circuit (4) comprises a shift register (41) which has n stages (S₁ to S_(n)) and n outputs (A₁ to A_(n)), and in that a second control signal (R_(P)) can be supplied to the shift register at the input (E) thereof for controlling the consecutive rows 1 to n, which second control signal activates the outputs (A₁ to A_(n)) of the shift register (41) consecutively in dependence on a clock signal (T).
 5. A circuit arrangement as claimed in claim 2, characterized in that the second control signal (R_(P)) is capable of switching off all n row outputs (Z₁ to Z_(n)) by means of the logic functions (L₁ to L_(n)) during the control of a line (Z₃, Z₄) that is not to be displayed in the partial mode.
 6. A circuit arrangement as claimed in claim 1, characterized in that a control logic (5) in the column drive circuit (3) generates the first control signal (R_(E)) in dependence on a partial mode and supplies it to the row drive circuit (4).
 7. A circuit arrangement as claimed in claim 1, characterized in that the column drive circuit (3) supplies no column voltages to the column outputs (A₁ to A_(m)) in the case of a line (Z₃, Z₄) that is not to be displayed.
 8. A circuit arrangement as claimed in claim 1, characterized in that the frequency of the clock signal (T) can be increased in the case of one or several consecutive rows (Z₃, Z₄) that is or are not to be displayed.
 9. A row drive circuit (4) for controlling n rows of a display device (2) having n outputs (A₁ to A_(n)), with a logic function (L₁ to L_(n)) connected in front of each row output (Z₁ to Z_(n)), by means of which function the row outputs (Z₁ to Z_(n)) can be deactivated/activated in dependence on a partial mode upon the supply of a first control signal (R_(E)).
 10. A display device (2) comprising a circuit arrangement as claimed in claim
 1. 11. An electronic appliance comprising a display device (2) as claimed in claim
 10. 12. A method of realizing a partial mode wherein a display device (2) is controlled by a circuit arrangement comprising a row drive circuit (4) for driving the n rows and a column drive circuit (3) for supplying column voltages, wherein the n rows are sequentially controlled from 1 to n and column voltages necessary for displaying the corresponding picture data of this row are supplied to the m columns, and wherein all row outputs (Z₁ to Z_(n)) are deactivated by a first control signal (R_(E)) in the control of a row (Z₃, Z₄) not to be displayed in the realization of a partial mode, while all row outputs (Z₁ to Z_(n)) are activated again by means of the first control signal (R_(E)) for the control of a row (Z₁, Z₂, Z₅) that is to be displayed in the partial mode. 